Structure and Function of the Bacterial Genome. Charles J. Dorman

Structure and Function of the Bacterial Genome - Charles J. Dorman


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al. 2008; Rodriguez and Harry 2012; van Baarle and Bramkamp 2010).

      Genetic elimination of the Min system and of nucleoid occlusion is deleterious for cell growth in rich medium, but the mutants can grow and divide in minimal medium (Bernhardt and de Boer 2005; Yu and Margolin 1999). This suggests that additional systems exist to ensure chromosome segregation and cell division (Bailey et al. 2014; Cambridge et al. 2014). A link between the Ter‐matS‐binding MatP protein and ZapB connects the Ter macrodomain of the chromosome to the divisome's ZapB‐ZapA‐FtsZ complex (Espéli et al. 2012) and this may afford the nucleoid itself a role in determining Z ring placement (Rowlett and Margolin 2015; Yu and Margolin 1999).

      Macrodomains play important roles in determining the choreography of the daughter chromosomes, as these segregate prior to cell division (Espéli et al. 2008). They also correlate with global gene expression patterns, suggesting that the overall gene expression programme of the cell is written into the architecture of the nucleoid (Cameron et al. 2017; Sobetzko 2016; Sobetzko et al. 2012). To appreciate the significance of the connections between nucleoid structure and gene expression, it will be necessary to consider the contributions made to both by variable DNA structure and NAPs.

      DNA in bacterial cells is maintained in an underwound state and this affects the shape that the DNA duplex adopts as it seeks to adopt a minimal energy conformation. The underwinding arises due to a deficit in helical turns, i.e. the number of times the two DNA strands twist around the duplex axis. The twist deficiency imparts torsional stress to the duplex, which is relieved by allowing the duplex to adopt a writhed confirmation in which the helical axis coils around itself. This coiling of the already coiled DNA duplex creates supercoiling and has the effect of making the DNA molecule more compact. In the context of the nucleoid, such compaction assists with solving the problem of packaging the genetic material within the cell. The most supercoiled parts of the chromosome form branches, facilitating further compaction.

      

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      For further information, see Lopez et al. (2012) and Postow et al. (2001).

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